The functional asymmetry of cosN, the nicking site for bacteriophage lambda DNA packaging, is dependent on the terminase binding site, cosB.

cosN is the site at which terminase, the DNA packaging enzyme of phage lambda, introduces staggered nicks into viral concatemeric DNA to initiate genome packaging. Although the nick positions and many of the base pairs of cosN show 2-fold rotational symmetry, cosN is functionally asymmetric. That is, the cosN G2C mutation in the left half-site (cosNL) causes a strong virus growth defect whereas the symmetrically disposed cosN C11G mutation in the right half-site (cosNR) does not affect virus growth. The experiments reported here test the proposal that the genetic asymmetry of cosN results from terminase interactions with cosB, a binding site to the right of cosN. In the presence of cosB, the left half-site mutation, cosN G2C, strongly affected the cos cleavage reaction, while the symmetric right half-site mutation, cosN C11G, had little effect. In the absence of cosB, the two mutations moderately reduced the rate of cos cleavage by the same amount. The results indicated that the functional asymmetry of cosNdepends on the presence of cosB. A model is discussed in which terminase-cosN interactions in the nicking complex are assisted by anchoring of terminase to cosB.

Bacteriophage lambda DNA packaging: DNA site requirements for termination and processivity.

Bacteriophage lambda chromosomes are processively packaged into preformed shells, using end-to-end multimers of intracellular viral DNA as the packaging substate. A 200 bp long DNA segment, cos, contains all the sequences needed for DNA packaging. The work reported here shows that efficient DNA packaging termination requires cos's I2 segment, in addition to the required termination subsite, cosQ, and the nicking site, cosN. Efficient processivity requires cosB, in addition to cosQ and cosN. An initiation-defective mutant form of cosB sponsored efficient processivity, indicating that the terminase-cosB interactions required for termination are less stringent than those required at initiation. The finding that an initiation-defective form of cosB is functional for processivity allows a re-interpretation of a similar finding, obtained previously, that the initiation-defective cosB of phage 21 is functional for processivity by the lambda packaging machinery. The cosBphi21 result can now be interpreted as indicating that interactions between cosBphi21 and lambda terminase, while insufficient for initiation, function for processivity.

Defining cosQ, the site required for termination of bacteriophage lambda DNA packaging.

Bacteriophage lambda is a double-stranded DNA virus that processes concatemeric DNA into virion chromosomes by cutting at specific recognition sites termed cos. A cos is composed of three subsites: cosN, the nicking site; cosB, required for packaging initiation; and cosQ, required for termination of chromosome packaging. During packaging termination, nicking of the bottom strand of cosN depends on cosQ, suggesting that cosQ is needed to deliver terminase to the bottom strand of cosN to carry out nicking. In the present work, saturation mutagenesis showed that a 7-bp segment comprises cosQ. A proposal that cosQ function requires an optimal sequence match between cosQ and cosNR, the right cosN half-site, was tested by constructing double cosQ mutants; the behavior of the double mutants was inconsistent with the proposal. Substitutions in the 17-bp region between cosQ and cosN resulted in no major defects in chromosome packaging. Insertional mutagenesis indicated that proper spacing between cosQ and cosN is required. The lethality of integral helical insertions eliminated a model in which DNA looping enables cosQ to deliver a gpA protomer for nicking at cosN. The 7 bp of cosQ coincide exactly with the recognition sequence for the Escherichia coli restriction endonuclease, EcoO109I.

Endonuclease and helicase activities of bacteriophage lambda terminase: changing nearby residue 515 restores activity to the gpA K497D mutant enzyme.

Terminase, the DNA packaging enzyme of bacteriophage lambda, is a heteromultimer of gpNu1 and gpA subunits. In an earlier investigation, a lethal mutation changing gpA residue 497 from lysine to aspartic acid (K497D) was found to cause a mild change in the high-affinity ATPase that resides in gpA and a severe defect in the endonuclease activity of terminase. The K497D terminase efficiently sponsored packaging of mature lambda DNA into proheads. In the present work, K497D terminase was found to have a severe defect in the cohesive end separation, or helicase, activity. Plaque-forming pseudorevertants of lambda A K497D were found to carry mutations in A that suppressed the lethality of the A K497D mutation. The two suppressor mutations identified, A E515G and A E515K, affected residue 515, which is located near the putative P-loop of gpA. A codon substitution study of codon 515 showed that hydrophobic and basic residues suppress the K497D defect, but hydrophilic and acidic residues do not. The E515G change was demonstrated to reverse the endonuclease and helicase defects caused by the K497D change. Moreover, the gpA K497D E515G enzyme was found to have kinetic constants for the high-affinity ATPase center similar to those of the wild type enzyme, and the endonuclease activity of the K497D E515G enzyme was stimulated by ATP to an extent similar to the ATP stimulation of the endonuclease activity of the wild type enzyme.

ATPase center of bacteriophage lambda terminase involved in post-cleavage stages of DNA packaging: identification of ATP-interactive amino acids.

Terminase is the enzyme that mediates lambda DNA packaging into the viral prohead. The large subunit of terminase, gpA (641 amino acid residues), has a high-affinity ATPase activity (K(m)=5 microM). To directly identify gpA's ATP-interacting amino acids, holoterminase bearing a His(6)-tag at the C terminus of gpA was UV-crosslinked with 8-N(3)-[alpha-(32)P]ATP. Tryptic peptides from the photolabeled terminase were purified by affinity chromatography and reverse-phase HPLC. Two labeled peptides of gpA were identified. Amino acid sequencing failed to show the tyrosine residue of the first peptide, E(43)SAY(46)QEGR(50), or the lysine of the second peptide, V(80)GYSK(84)MLL(87), indicating that Y(46) and K(84) were the 8-N(3)-ATP-modified amino acids. To investigate their roles in lambda DNA packaging, Y(46) was changed to E, A, and F, and K(84) was changed to E and A. Purified His(6)-tagged terminases with changes at residues 46 and 84 lacked the gpA high-affinity ATPase activity, though the cos cleavage and cohesive end separation activities were near to those of the wild-type enzyme. In virion assembly reactions using virion DNA as a packaging substrate, the mutant terminases showed severe defects. In summary, the results indicate that Y(46) and K(84) are part of the high-affinity ATPase center of gpA, and show that this ATPase activity is involved in the post-cos cleavage stages of lambda DNA packaging.

A mutation correcting the DNA interaction defects of a mutant phage lambda terminase, gpNu1 K35A terminase.

Terminase, the DNA packaging enzyme of bacteriophage lambda, is a heteromultimer composed of gpNu1 (181 aa) and gpA (641 aa) subunits, encoded by the lambda Nu1 and A genes, respectively. Similarity between the deduced amino acid sequences of gpNu1 and gpA and the nucleotide binding site consensus sequence suggests that each terminase subunit has an ATP reactive center. Terminase has been shown to have two distinct ATPase activities. The gpNu1 subunit has a low-affinity ATPase stimulated by nonspecific DNA and gpA has a high-affinity ATPase. In previous work, a mutant terminase, gpNu1 K35A holoterminase, had a mild defect in interactions with DNA, such that twofold increased DNA concentrations were required both for full stimulation of the low-affinity ATPase and for saturation of the cos cleavage reaction. In addition, the gpNu1 K35A terminase exhibited a post-cleavage defect in DNA packaging that accounted for the lethality of the Nu1 K35A mutation [Y. Hwang and M. Feiss (1997) Virology 231, 218-230]. In the work reported here, a mutation in the turn of the putative helix-turn-helix DNA binding domain has been isolated as a suppressor of the gpNu1 K35A change. This suppressor mutation causes the change A14V in gpNu1. A14V reverses the DNA-binding defects of gpNu1 K35A terminase, both for stimulation of the low-affinity ATPase and for saturation of the cos cleavage defect. A14V suppresses the post-cleavage DNA packaging defect caused by the gpNu1 K35A change.

Cloning, expression, and biochemical characterization of hexahistidine-tagged terminase proteins.

The terminase enzyme from bacteriophage lambda is composed of two viral proteins (gpA, 73.2 kDa; gpNu1, 20.4 kDa) and is responsible for packaging viral DNA into the confines of an empty procapsid. We are interested in the genetic, biochemical, and biophysical properties of DNA packaging in phage lambda and, in particular, the nucleoprotein complexes involved in these processes. These studies require the routine purification of large quantities of wild-type and mutant proteins in order to probe the molecular mechanism of DNA packaging. Toward this end, we have constructed a hexahistidine (hexa-His)-tagged terminase holoenzyme as well as hexa-His-tagged gpNu1 and gpA subunits. We present a simple, one-step purification scheme for the purification of large quantities of the holoenzyme and the individual subunits directly from the crude cell lysate. Importantly, we have developed a method to purify the highly insoluble gpNu1 subunit from inclusion bodies in a single step. Hexa-His terminase holoenzyme is functional in vivo and possesses steady-state and single-turnover ATPase activity that is indistinguishable from wild-type enzyme. The nuclease activity of the modified holoenzyme is near wild type, but the reaction exhibits a greater dependence on Escherichia coli integration host factor, a result that is mirrored in vivo. These results suggest that the hexa-His-tagged holoenzyme possesses a mild DNA-binding defect that is masked, at least in part, by integration host factor. The mild defect in hexa-His terminase holoenzyme is more significant in the isolated gpA-hexa-His subunit that does not appear to bind DNA. Moreover, whereas the hexa-His-tagged gpNu1 subunit may be reconstituted into a holoenzyme complex with wild-type catalytic activities, gpA-hexa-His is impaired in its interactions with the gpNu1 subunit of the enzyme. The results reported here underscore that a complete biochemical characterization of the effects of purification tags on enzyme function must be performed prior to their use in mechanistic studies.

Mutations that extend the specificity of the endonuclease activity of lambda terminase.

Terminase, an enzyme encoded by the Nu1 and A genes of bacteriophage lambda, is crucial for packaging concatemeric DNA into virions. cosN, a 22-bp segment, is the site on the virus chromosome where terminase introduces staggered nicks to cut the concatemer to generate unit-length virion chromosomes. Although cosN is rotationally symmetric, mutations in cosN have asymmetric effects. The cosN G2C mutation (a G-to-C change at position 2) in the left half of cosN reduces the phage yield 10-fold, whereas the symmetric mutation cosN C11G, in the right half of cosN, does not affect the burst size. The reduction in phage yield caused by cosN G2C is correlated with a defect in cos cleavage. Three suppressors of the cosN G2C mutation, A-E515G, A-N509K, and A-R504C, have been isolated that restore the yield of lambda cosN G2C to the wild-type level. The suppressors are missense mutations that alter amino acids located near an ATPase domain of gpA. lambda A-E515G, A-N509K, and A-R504C phages, which are cosN+, also had wild-type burst sizes. In vitro cos cleavage experiments on cosN G2C C11G DNA showed that the rate of cleavage for A-E515G terminase is three- to fourfold higher than for wild-type terminase. The A-E515G mutation changes residue 515 of gpA from glutamic acid to glycine. Uncharged polar and hydrophobic residues at position 515 suppressed the growth defect of lambda cosN G2C C11G. In contrast, basic (K, R) and acidic (E, D) residues at position 515 failed to suppress the growth defect of lambda cosN G2C C11G. In a lambda cosN+ background, all amino acids tested at position 515 were functional. These results suggest that A-E515G plays an indirect role in extending the specificity of the endonuclease activity of lambda terminase.

Termination of packaging of the bacteriophage lambda chromosome: cosQ is required for nicking the bottom strand of cosN.

Termination of packaging of the lambda chromosome involves completion of translocation of the DNA into the head shell, and conversion of the translocation complex into a cleavage complex. The cleavage reaction introduces staggered nicks into the downstream cosN to generate the right cohesive end of the chromosome. cosQ, a site adjacent to cosN, was found to be required for nicking the bottom strand of cosN; bottom strand nicking was also sequence-specific for bps at the nick site. Nicking of the top strand of cosN (cosNL) was stimulated by cosQ, but fidelity and efficiency of cosNL nicking were largely dictated by other cos subsites (i.e. cosB and I2). Aberrant top-strand cleavage within cosQ was observed in the absence of I2, and nicking at a site 8 nt 5' to the normal cosNL nick site occurred in the absence of cosB. The presence of cosQ was found to be insufficient to arrest DNA translocation in vivo, indicating that cosQ, per se, is not a packaging stop signal. A model is presented in which the role of cosQ is to depolarize the asymmetric arrangement of terminase protomers in the translocation complex so that protomers are configured to match the 2-fold rotational symmetry of cosN.

Genetic evidence that recognition of cosQ, the signal for termination of phage lambda DNA packaging, depends on the extent of head filling.

Packaging a phage lambda chromosome involves cutting the chromosome from a concatemer and translocating the DNA into a prohead. The cutting site, cos, consists of three subsites: cosN, the nicking site; cosB, a site required for packaging initiation; and cosQ a site required for termination of packaging. cosB contains three binding sites (R sequences) for gpNu1, the small subunit of terminase. Because cosQ has sequence identity to the R sequences, it has been proposed that cosQ is also recognized by gpNu1. Suppressors of cosB mutations were unable to suppress a cosQ point mutation. Suppressors of a cosQ mutation (cosQ1) were isolated and found to be of three sorts, the first affecting a base pair in cosQ. The second type of cosQ suppression involved increasing the length of the phage chromosome to a length near to the maximum capacity of the head shell. A third class of suppressors were missense mutations in gene B, which encodes the portal protein of the virion. It is speculated that increasing DNA length and altering the portal protein may reduce the rate of translocation, thereby increasing the efficiency of recognition of the mutant cosQ. None of the cosQ suppressors was able to suppress cosB mutations. Because cosQ and cosB mutations are suppressed by very different types of suppressors, it is concluded that cosQ and the R sequences of cosB are recognized by different DNA-binding determinants.

Mutations affecting lysine-35 of gpNu1, the small subunit of bacteriophage lambda terminase, alter the strength and specificity of holoterminase interactions with DNA.

The small subunit of lambda terminase, gpNu1, contains a low-affinity ATPase activity that is stimulated by nonspecific dsDNA. The location of the gpNu1 ATPase center is suggested by a sequence match between gpNu1 (29-VLRGGGKG-36) and the phosphate-binding loop, or P-loop (GXXXXGKT/S), of known ATPase. The proposed P-loop of gpNu1 is just downstream of a putative helix-turn-helix DNA-binding motif, located between residues 5 and 24. Published work has shown that changing lysine-35 of the proposed P-loop of gpNu1 alters the response of the ATPase activity to DNA, as follows. The changes gpNu1 k35A and gpNu1 K35D increase the level of DNA required for maximal stimulation of the gpNu1 ATPase by factors of 2- and 10-fold, respectively. The maximally stimulated ATPase activities of the mutant enzymes are indistinguishable from that of the wild-type enzyme. In the present work, the effects of changing lysine-35 on the cos-cleavage and DNA-packaging activities of terminase were examined. In vitro, the gpNu1 K35A enzyme cleaved cos as efficiently as the wild-type enzyme, but required a 2-fold increased level of substrate DNA for saturation, suggesting a slight reduction in DNA affinity. In a crude DNA-packaging system using cleaved lambda DNA as substrate, the gpNu1 K35A enzyme had a 10-fold defect. In vivo, lambda Nu1 K35A showed a 2-fold reduction in cos cleavage, but no packaged DNA was detected. The primary defect of the gpNu1 K35A enzyme was concluded to be in a post-cos-cleavage step of DNA packaging. In in vitro cos-cleavage experiments, the gpNu1 K35D enzyme had a 10-fold increased requirement for saturation by substrate DNA. Furthermore, the cos-cleavage activity of gpNu1 K35D enzyme was strongly inhibited by the presence of nonspecific DNA, indicating that the gpNu1 K35D enzyme is unable to discriminate effectively between cos and nonspecific DNA. No cos cleavage was observed in vivo for lambda Nu1 K35D, a result consistent with the discrimination defect found in vitro for the gpNu1 K35D enzyme. In a crude packaging system the gpNu1 K35D enzyme had a 200-fold defect; in a purified packaging system, the gpNu1 K35D enzyme was found to be unable to discriminate between lambda DNA and nonspecific phage T7 DNA, a result indicating that the gpNu1 K35D enzyme is also defective in discriminating between lambda DNA and nonspecific DNA during DNA packaging.

Mutations in Nu1, the gene encoding the small subunit of bacteriophage lambda terminase, suppress the postcleavage DNA packaging defect of cosB mutations.

The linear double-stranded DNA molecules in lambda virions are generated by nicking of concatemeric intracellular DNA by terminase, the lambda DNA packaging enzyme. Staggered nicks are introduced at cosN to generate the cohesive ends of virion DNA. After nicking, the cohesive ends are separated by terminase; terminase bound to the left end of the DNA to be packaged then binds the empty protein shell, i.e., the prohead, and translocation of DNA into the prohead occurs. cosB, a site adjacent to cosN, is a terminase binding site. cosB facilitates the rate and fidelity of the cosN cleavage reaction by serving as an anchoring point for gpNu1, the small subunit of terminase. cosB is also crucial for the formation of a stable terminase-DNA complex, called complex I, formed after cosN cleavage. The role of complex I is to bind the prohead. Mutations in cosB affect both cosB functions, causing mild defects in cosN cleavage and severe packaging defects. The lethal cosB R3- R2- R1- mutation contains a transition mutation in each of the three gpNu1 binding sites of cosB. Pseudorevertants of lambda cosB R3- R2- R1- DNA contain suppressor mutations affecting gpNu1. Results of experiments that show that two such suppressors, Nu1ms1 and Nu1ms3, do not suppress the mild cosN cleavage defect caused by the cosB R3- R2- R1- mutation but strongly suppress the DNA packaging defect are presented. It is proposed that the suppressing terminases, unlike the wild-type enzyme, are able to assemble a stable complex I with cosB R3- R2- R1- DNA. Observations on the adenosine triphosphatase activities and protease susceptibilities of gpNu1 of the Nu1ms1 and Nu1ms3 terminases indicate that the conformation of gpNu1 is altered in the suppressing terminases.

Mutations affecting the high affinity ATPase center of gpA, the large subunit of bacteriophage lambda terminase, inactivate the endonuclease activity of terminase.

Phage lambda terminase carries out the cos cleavage reaction that generates mature chromosomes from immature concatemeric DNA. The ATP-stimulated endonuclease activity of terminase is located in gpA, the large terminase subunit. There is a high affinity ATPase center in gpA, and a match to the conserved P-loop of known ATPases is found starting near residue 490. Changing the conserved P-loop lysine at residue 497 of gpA affects the high affinity ATPase activity of terminase. In the present work, mutations causing the gpA changes K497A and K497D were found to be lethal, and phages carrying these mutations were defective in cos cleavage, in vivo. Purified K497A and K497D enzymes cleaved cos in vitro at rates reduced from the wild-type rate by factors of 1000 and 2000, respectively. The strong defects in cos cleavage are sufficient to explain the lethality of the K497A and K497D defects. In in vitro packaging studies using mature (cleaved) phage DNA, the K497A enzyme was indistinguishable from the wild-type enzyme, and the K497D enzyme showed a mild packaging defect under limiting terminase conditions. In a purified DNA packaging system, the wild-type and K497D enzymes showed similar packaging activities that were stimulated to half-maximal levels at about 3 microM ATP, indicating that the K497D change does not affect DNA translocation. In sum, the work indicates that the high affinity ATPase center of gpA is involved in stimulation of the endonuclease activity of terminase.

Kinetic and mutational dissection of the two ATPase activities of terminase, the DNA packaging enzyme of bacteriophage Chi.

Terminase the DNA packaging enzyme of bacteriophage chi, is a heteromultimer of gpNul (21 kDa) and gpA (74 kDa) subunits, encoded by the chi Nul and A genes, respectively. Sequence comparisons indicate that both gpNu1 and gpA have a match to the P-loop motif of ATPase centers, which is a glycine-rich segment followed by a lysine. By site-specific mutagenesis, we changed the lysines of the putative P-loops of gpNul (k35) and gpA (K497) to arginine, alanine, or aspartic acid, and studied the mutant enzymes by kinetic analysis and photochemical cross-linking with 8-azido-ATP. Both the gpNul and gpA subunits of wild-type terminase were covalently modified with 8-N3[32P] ATP in the presence of UV light. Saturation occurred with apparent dissociation constants of 508 and 3.5 microM for gpNul and gpA, resepctively. ATPase assays showed two activities: a low-affinity activity (Km=469 microM), and a high-affinity activity (Km=4.6 microM). The gpNul K35A and gpNul K35D mutant terminases showed decreased activity in the low-affinity ATPase activity. The reduced activities of these enzymes were recovered when 10 times more DNA was added, suggesting that the primary defect of the enzymes is alteration of the nonspecific, double-stranded DNA binding activity of terminase. ATPase assays and photolabeling of the gpA K497A and gpA K497D mutant terminases showed reduced affinity for ATP at the high-affinity site which was not restored by increased DNA. In summary, the results indicate the presence of a low-affinity, DNA-stimulated ATPase center in gpNul, and a high-affinity site in gpA.

A defined system for in vitro lambda DNA packaging.

We constructed a defined in vitro system for packaging lambda DNA which is composed of purified proheads, the noncapsid proteins terminase and gpFI, and the Escherichia coli DNA binding/bending protein IHF. The defined packaging system: (i) is free from endogenous ATP, DNAs, and DNases and (ii) packages 30% of the input mature lambda DNA efficiently. In this defined packaging system, IHF and gpFI make modest contributions to packaging efficiency. The defined packaging reactions showed that DNA packaging gave a linear response to the concentration of mature lambda DNA and terminase. DNA packaging showed a sigmoidal relationship with respect to the concentration of ATP and proheads.

Virus DNA packaging: the strategy used by phage lambda.

Phage lambda, like a number of other large DNA bacteriophages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is co-ordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the lambda DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric lambda DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN to complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endonuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNu1, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in lambda has aspects that differ from other lambda DNA transactions. Unlike the site-specific recombination system of lambda, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complex, and unlike the DNA replication system of lambda, the same protein machinery is used for both initiation and translocation during lambda DNA packaging.

Mutational analysis of the prohead binding domain of the large subunit of terminase, the bacteriophage lambda DNA packaging enzyme.

Terminase, the DNA packaging enzyme of bacteriophage lambda, is made up of two subunits, gpNul and gpA, the products of the Nu1 and A genes. The activities of terminase include DNA binding, cos cleavage and prohead binding. Specificity domains within the structure of terminase have previously been defined by genetic studies of lambda-21 hybrids. The prohead binding domain of terminase is localized to the last 32 amino acid residues of gpA. Mutations in the prohead binding domain of gpA were constructed by introducing the corresponding amino acids from gp2, the gpA analog of bacteriophage 21. The last five residues of gpA can be replaced with little effect on the burst size of lambda. A phage with a replacement of the last six residues of gpA with the corresponding residues of gp2 was unable to form plaques, indicating that the sixth-to-last residues of gpA is crucial for prohead binding. Site-specific mutagenesis of the sixth-to-last position of gpA indicated that the sixth-to-last residue of gpA must be hydrophobic, of the seven amino acids tested, only isoleucine and valine can substitute for leucine at this position. Although the last five residues of gp2 were functional when they replaced the last five residues of gpA, two results indicated that the last five residues of gpA functioned better than the corresponding residues of gp2. First, the presence of a valine residue at the sixth-to-last position of gpA allowed plaque formation, whereas replacement of the last six residues of gpA with those of gp2, which substitutes a valine residue at the sixth-to-last position, was lethal. The second set of results indicating that the last five residues of gpA function better than the gp2 residues were obtained by study of revertants of lethal substitution mutations. In constructing the replacement mutations, a short linker was inserted into the C terminus of the A gene; this insertion created a short duplication of the end of the A gene, so that the normal C-terminal codons were located downstream of the stop codon of the A gene in the substitution mutants. Revertants of the lethal substitution mutations were obtained in which a mutation in the stop codon resulted in addition of the last five residues of gpA to the end of the substitution terminase.(ABSTRACT TRUNCATED AT 400 WORDS)

Specific interaction of terminase, the DNA packaging enzyme of bacteriophage lambda, with the portal protein of the prohead.

Terminase, the bacteriophage lambda DNA packaging protein, is a heteromultimer of two subunits, gpNu1 and gpA, the products of genes Nu1 and A, resp. Phage 21 is a lambdoid phage that produces a terminase similar to that of lambda terminase, the subunits of 21 terminase, gp1 and gp2, have the same domain structures of their lambda analog, gpNu1 and gpA, respectively. The lambda and 21 terminases have different DNA binding and prohead binding specificities. When the C-terminal 32 amino residues of gpA replace the C-terminal 32 residues of gp2, the resulting chimeric terminase specifically uses lambda proheads, indicating that the C-terminal 32 residues of gpA are a specificity domain for prohead binding. A second chimeric terminase, in which the C-terminal six residues of gpA are replaced by the C-terminal six residues of gp2, is unable to utilize lambda proheads, and a lambda phage producing this terminase, lambda Are636, is unable to form plaques. In the present work, a pseudorevertant of lambda Are636 was isolated that contained a mutation Bms8, affecting the prohead. The B gene encodes the portal protein of lambda proheads, which forms the special vertex that is thought to serve as (1) the site of DNA entry into the prohead during packaging, (2) the site for DNA exit during DNA injection, and (3) the site of tail attachment during virion assembly. Bms8 is predicted to change residue 331 of gpB from proline to serine. Burst size measurements and in vitro DNA packaging experiments demonstrated allele-specific interactions between the Are636 terminase and Bms8 proheads. That is, wild-type terminase interacted more efficiently with wild-type proheads than with Bms8 proheads, and Are636 terminase interacted with Bms8 proheads more efficiently than with wild-type proheads. Prohead binding by lambda terminase is stimulated by an assembly catalyst, gpFI. In vitro packaging extracts lacking gpFI were used under conditions in which packaging was gpFI-independent. In the absence of gpFI, Are636 terminase interacted most efficiently with Bms8 proheads, and wild-type terminase interacted most efficiently with wild-type proheads. The allele-specific interactions in the absence of gpFI indicate that the Are636 and Bms8 mutations affect direct interactions between terminase and the portal protein, rather than acting indirectly by altering the interactions of terminase and gpB and gpFI.

The role of cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda, in the nicking reaction.

cosB is the binding site for terminase, the DNA packaging enzyme of ai-12581mbda, and cosN is the adjacent site at which terminase gm-07228es staggered nicks to generate mature lambda DNA molecules. There are three binding sites (R3, R2 and R1) within cosB for gpNu1, the small subunit of terminase. A particular transition mutation of R1, known to weaken binding of gpNu1 to R1, has been introduced into the other R sites, and in the present work the effects of R site mutations on nicking of cosN have been examined. Nicking experiments performed in the presence of ATP suggest that the most profound cosB mutation tested (the R3-R2-R1- mutation) would, at most, reduce cos nicking to congruent to 30% of the level observed for the wild-type substrate. In the presence of ATP, the R3-R2-R1- mutation had no significant effect on terminase nicking of the 1 strand and reduced r-strand nicking to 35% of the wild-type level. The other cosB mutations had no effect on the nicking of either DNA strand when nucleotide was added, but in the absence of ATP, most of the cos mutations resulted in some form of cosN nicking defect; the nicking defects, however, are milder than the in vivo packaging defects that result from the mutations. Quantitatively, only the effect of the R3-R2-R1- mutation on in vitro cosN nicking is reflective of the growth defect exhibited by a R3-R2-R1- phage but the nicking defect is only observed when ATP is omitted from the reaction. The proposal that the cosB mutations primarily affect DNA packaging rather than cosN nicking is discussed. All of the cosB mutations affect r-strand nicking to a greater extent than 1-strand nicking, implying that the interaction of terminase with the left half of cosN occurs via the direct recognition of cosNL by terminase. The level of DNA substrate required for half-maximal cos nicking is approximately equivalent for reactions performed in the presence or absence of ATP, indicating that ATP does not increase the affinity of terminase for cosB. ATP does accelerate the rate of cos nicking, suggesting that the role of ATP in promoting nicking of the cosB- DNAs is primarily to increase the rate of conversion of a cosN-terminase complex into product. A possible fourth R site, R4, is located on the other side of cosN from cosB.(ABSTRACT TRUNCATED AT 400 WORDS)

A site required for termination of packaging of the phage lambda chromosome.

Lambda chromosomes are cut and packaged from concatemeric DNA by phage enzyme terminase. Terminase initiates DNA packaging by binding at a site called cosB and introducing staggered nicks at an adjacent site, cosN, to generate the left cohesive end of the DNA molecule to be packaged. After DNA packaging terminase recognizes and cuts the terminal cosN, an event that does not require a wild-type cosB. In this work a site, called cosQ, has been identified that is required for termination of DNA packaging. cosQ, defined by mutations in a sequence called R4, is located approximately 30 bp upstream from cosN. The order of sites is cosQ-cosN-cosB. Helper packaging of repressed, tandem prophage chromosomes demonstrated that a cosQ point mutation affects DNA packaging only when placed at the terminal cos site, whereas cosB mutations only affect packaging initiation. In vitro packaging studies confirmed that cosQ mutations do not affect packaging initiation. In vivo studies indicated that cosQ mutations do not affect cutting of initial cos sites but do cause a defect in packaging termination. cosQ mutants accumulated expanded phage heads, indicating that cosQ mutations affect a step that occurs after packaging of a substantial length of phage DNA. These results show that cosQ mutations define a site required for use of cos sites present at the ends of lambda chromosomes undergoing packaging. Available evidence suggests that other viruses, including phages T3 and T7 and the herpesviruses, may ultimately prove to use cosQ-like sites for packaging termination.